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Instead of 2*i, I carelessly wrote 2i:

int foo(int i)
    return 2i;

I expected the compiler to catch the error. But it did not. So is 2i a valid statement in C? If so what does it do? Puzzled!

I compiled using gcc version 5.3.0 and here is the assembly output:

    .file   "strange.c"
    .globl  foo
    .type   foo, @function
    pushq   %rbp
    .cfi_def_cfa_offset 16
    .cfi_offset 6, -16
    movq    %rsp, %rbp
    .cfi_def_cfa_register 6
    movl    %edi, -4(%rbp)
    popq    %rbp
    .cfi_def_cfa 7, 8
    .size   foo, .-foo
    .ident  "GCC: (GNU) 5.3.0"
    .section    .note.GNU-stack,"",@progbits
share|improve this question
What compiler is that? – iharob Feb 3 at 17:28
I don't work with _Complex numbers. After some reading in the standard and the provided link, I think @iharob's answer is correct. – Olaf Feb 3 at 17:37
@Olaf The fastet Fourier Transform in the West fftw uses the _Complex type. I found this out while writing a data processing software for my thesis (Physics actually, not computer science or alike) - (I had to apply a low pass filter, so convolution so Fast Fourier Transform, so fftw). – iharob Feb 3 at 17:41
@iharob: Hmm, is that faster than the ffte and if not, am I allowed to use the faster if I live in the west, but east of you? ;-) Seriously: thanks for the info. As it looks, the C standard does not even support a similar simple notation with C11. – Olaf Feb 3 at 17:48
A very good example of ".. not 'Eureka' but 'That's funny...'"! – Rad Lexus Feb 3 at 18:47
up vote 104 down vote accepted

This is a gcc extension, and 2i is the imaginary constant enter image description here. So you can write a complex number like so:

#include <complex.h>

_Complex x = 4 + 5i;
share|improve this answer
Wow, that came as a surprise! Will you tell me why it worked even when i did not include complex.h header file? – daltonfury42 Feb 3 at 17:39
@daltonfury42 The header is for the _Complex type, 2i is a constant (as gcc understands it). Add the std=c99 or std=c11 flag combined with -Wall and you shall see a warning. Also, indeed it does not return 0 but since the return type should be _Complex and the value 0 + 2i, you can't inspect it with printf(). So perhaps that is just the real part 0! – iharob Feb 3 at 17:40
@daltonfury42: You don't have to #include <float.h> (or math.h) to get support for floating point constants either. – Olaf Feb 3 at 17:45
@daltonfury42 That's right. Header files don't change the language syntax, they just declare things like variables, functions, types, etc. – Barmar Feb 3 at 17:54
@daltonfury42 Although it could have been possible for recognition of this syntax to be controlled by a #pragma, which complex.h could issue. But they didn't do it this way. – Barmar Feb 3 at 17:55

2i is a gcc extension for a complex integer literal, a pure imaginary number twice the square root of -1. This extension is supported by clang as well.

It is somewhat surprising that your compiling with gcc 5.4.0 produces the posted assembly output:

  • Compiling on I get a compilation error from gcc 5.3.0: error: cannot convert '__complex__ int' to 'int' in return.
  • The posted assembly code for function foo is incorrect: it does not return 0. Converting the complex integer constant 2i to int should return its real part 0.

Conversely, with clang 3.7, it compiles without a warning and generates optimum code, but of course not what you expect:

foo(int):                       # @foo(int)
    xorl    %eax, %eax

This syntax can be combined with other suffixes in any order. Compiling the code below with clang -Weverything gives me appropriate warnings warning: imaginary constants are a GNU extension [-Wgnu-imaginary-constant]:

#include <stdio.h>

int main() {
    /* complex integer literals */
    printf("sizeof(2i) = %zd\n", sizeof(2i));
    printf("sizeof(2ui) = %zd\n", sizeof(2ui));
    printf("sizeof(2li) = %zd\n", sizeof(2li));
    printf("sizeof(2lli) = %zd\n", sizeof(2lli));
    /* complex floating point literals */
    printf("sizeof(2.i) = %zd\n", sizeof(2.i));
    printf("sizeof( = %zd\n", sizeof(;
    printf("sizeof(2e0fi) = %zd\n", sizeof(2e0fi));
    printf("sizeof(2e0i) = %zd\n", sizeof(2e0i));
    /* alternate order */
    printf("sizeof(2il) = %zd\n", sizeof(2il));
    printf("sizeof(2ill) = %zd\n", sizeof(2ill));
    printf("sizeof(2.if) = %zd\n", sizeof(2.if));

    return 0;

It produces this output in my environment:

sizeof(2i) = 8
sizeof(2ui) = 8
sizeof(2li) = 16
sizeof(2lli) = 16
sizeof(2.i) = 16
sizeof( = 8
sizeof(2e0fi) = 8
sizeof(2e0i) = 16
sizeof(2il) = 16
sizeof(2ill) = 16
sizeof(2.if) = 8

Try the last one with your syntax coloring editor ;-)

share|improve this answer
Well, this is what I got when I used GCC 5.3.0 on my PC running Arch Linux. Here is my gcc configuration if you are interested. – daltonfury42 Feb 4 at 12:11

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